KR20150002437A - Horizontal rotary shuttle for sewing machine - Google Patents

Abstract

The present invention relates to a horizontal rotary shuttle. The horizontal shuttle for a sewing machine includes: an outer shuttle part; an inner shuttle part rotatably accommodated in the outer shuttle part and having a shuttle shaft; a latch lever rotatably connected to the shuttle shaft and having a stopper; a bobbin sheet fitted around the shuttle shaft; an elastic element disposed between the bobbin sheet and the inner shuttle part; and a bobbin fitted around the bobbin sheet.

Description

{HORIZONTAL ROTARY SHUTTLE FOR SEWING MACHINE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a horizonatal rotary shuttle of a sewing machine and, more particularly, to a horizonal rotary shuttle which is used in a sewing machine and which is capable of quickly replacing a bobbin without risk of losing a part of the horizontal rotation shuttle, To a horizontal rotation shuttle having a mechanism.

1, there is shown a sectional view of a sewing machine having an outer shuttle portion (not shown), an inner shuttle portion 10, a conical spring 11, a bobbin 12 and a latch lever 13 1 shows a conventional rotary shuttle. The inner shuttle 10 has a centrally located shuttle shaft 101 therein. The conical spring 11 is tapered from the top to the bottom and is fitted around the shuttle shaft 101 with the larger upper portion of the spring pushing directly on the bottom of the bobbin 12 to function as an elastic pushing member. The bobbin 12 can be resiliently pushed out of the inner shuttle portion 10 by the conical spring 11 when the latch lever 13 is rotated from a horizontal or locked position to a vertical or unlocked position . The conical spring 11 is arranged to provide frictional resistance to the bobbin 12 to prevent the bobbin 12 from idling and to allow the user to easily remove the bobbin 12 from the inner shuttle portion 10 I will.

The disadvantage of the first conventional rotary shuttle is that only one conical spring 11 is arranged to prevent the bobbin 12 from idling so that the frictional resistance provided to the bobbin 12 is unstable. Further, there is no other stop mechanism for restricting the conical spring 11 between the bobbin 12 and the inner shuttle portion 10 and the resiliently extending conical spring 11 to the inner shuttle portion 10 The conical spring 11 tends to protrude out of the inner shuttle portion 10 and be lost after the bobbin 12 is removed from the inner shuttle portion 10. To overcome the drawbacks of the first conventional spinning shuttle of the sewing machine, another spinning shuttle has been developed to prevent some of the spinning shutters from losing while replacing the bobbin.

See FIG. The second conventional rotary shuttle having a structure to prevent the loss of a portion of the rotary shuttle includes an outer shuttle portion (not shown), an inner shuttle portion 20, a conical spring 21, a bobbin seat 22, A slide prevention spring plate 23, a bobbin 24, and a latch lever 25. The inner shuttle 20 has a centrally located shuttle shaft 201 therein. The conical spring 21 tapers from the top to the bottom and is fitted around the shuttle shaft 201, at which time a larger upper portion of the spring presses the bottom of the bobbin sheet 22. The bobbin 24 and the slide prevention spring plate 22 are sequentially fitted around the bobbin sheet 22 so that the slide prevention spring plate 23 presses the bottom portion of the bobbin 24 upwardly, Lt; / RTI >

In a second conventional rotary shuttle, a stop screw 26 is spaced along the peripheral wall of the inner shuttle 20 and extends inwardly through the peripheral wall to contact the outer peripheral edge of the bobbin sheet 22 Thereby preventing the bobbin sheet 22 and the conical spring 21 from moving out of the inner shuttle portion 20. The difference between the outer diameter of the bobbin 24 and the inner diameter of the inner shuttle portion 20 is so small that it interferes with the axial movement of the bobbin 24 to and from the inner shuttle portion 20 The free end of the stop screw 26 and the outer circumferential edge of the bobbin sheet 22 must be located at a very small gap between the bobbin 24 and the inner shuttle portion 20, All portions, i.e., the inner shuttle portion 20, the bobbin 24, the bobbin sheet 22, and the stop screw 26 must be manufactured with precision. In addition, although the slide prevention spring plate 23 provides a stable frictional resistance to the bobbin 24, this spring plate increases the number of parts, thereby increasing the manufacturing cost of the rotary shuttle.

The main object of the present invention is to provide a sewing machine which can be used for a sewing machine and includes a passive elastic push mechanism which can quickly and conveniently replace a bobbin mounted on a horizontal spinning shuttle by simply pulling the latch lever to the unlocked position To provide a horizontal rotation shuttle which is very practical and convenient to use.

It is a further object of the present invention to provide an apparatus and method for disassembling a portion of a horizontal rotation shuttle, which comprises a reduced number of parts and which has an elastic push mechanism that reduces manufacturing costs and does not require a precisely machined elastic holding down mechanism, And to provide a horizontal rotation shuttle of a sewing machine capable of achieving the object of quickly replacing the bobbin.

To achieve the above objects and other objects, a horizontal rotation shuttle of a sewing machine according to a preferred embodiment of the present invention includes an outer shuttle portion, an inner shuttle portion, a bobbin sheet, an elastic element, a latch lever and a bobbin. The inner shuttle portion includes a hollow shuttle shaft housed in the outer shuttle portion to be rotatable about one axis with respect to the outer shuttle portion and centered thereon to align with the outer shuttle portion. The bobbin sheet is fitted around the shuttle shaft and includes a sleeve portion and a flange portion extending radially outward from the lower end of the sleeve portion. The elastic element is positioned between the inner shuttle portion and the bobbin sheet to resiliently push the bobbin sheet forward in this axial direction. The latch lever includes a pivotal end rotatably connected to the shuttle shaft via a pivot pin and a free end that selectively moves to a desired position and has a stopper on at least one of the two lateral edges . Then, the bobbin is mounted around the bobbin sheet.

The latch lever according to the invention is selectively rotatable between a locking position perpendicular to this axis and an unlocking position parallel to this axis. When the latch lever is rotated to the locked position, the two axially opposite ends of the bobbin are adjacent to the latch lever and the bobbin seat, respectively, such that the bobbin is defined between the latch lever and the bobbin seat. More specifically, when the latch lever is in the locked position, the bobbin has a lower end adjacent the flange portion of the bobbin sheet and an upper end located higher than the upper portion of the sleeve portion and adjacent the latch lever. On the other hand, when the latch lever is rotated to the unlock position, the bobbin sheet is pushed forward elastically by the elastic element until it abuts the stopper provided on the latch lever.

In a preferred embodiment, the flange portion of the bobbin sheet is provided with an annular groove on the lower side, and the elastic element is a conical spring tapered from the lower end to the upper end. The elastic element is positioned between the bobbin sheet and the inner shuttle portion, and the upper end of the elastic element is fixedly received in the annular groove of the bobbin sheet.

Further, the sleeve portion of the bobbin sheet has pin mounting holes and pin removing holes at two opposing positions. The pivot pin extends through the pin mounting hole and pivotally connects the latch lever to the shuttle shaft. The pin removal hole has a smaller diameter than the diameter of the pivot pin but allows the tool to extend through the pin removal hole to push the pivot pin out of the sleeve portion through the pin mounting hole. According to a preferred embodiment, the latch lever has a shallow recess at a predetermined position near the free end, which makes it convenient for the user to pull the latch lever.

The present invention is directed to a locking position in which the latch lever of the horizontal rotation shuttle confines the bobbin to the inner shuttle portion between the latch lever and the bobbin sheet or to an elastic element which pushes the bobbin sheet forwardly until the bobbin sheet is adjacent the stop provided with the latch lever To the unlocked position in which it can be pivoted to the unlocked position. Since only one elastic element is required, the horizontal rotation shuttle of the present invention can simplify the overall structural design. Further, using a bobbin seat and latch lever to limit the bobbin to the inner shuttle portion eliminates the need to use a highly precisely manufactured portion of the entire spin shuttle.

Thus, the horizontal rotation shuttle can greatly reduce manufacturing costs while achieving the same effect of resiliently pushing the bobbin sheet to a desired height in replacing the bobbin without risk of losing a portion of the horizontal rotation shuttle.

The structure and technical means employed by the present invention to achieve the above objects and other objects will be best understood by referring to the following detailed description of the preferred embodiments and accompanying drawings.
1 is an assembled sectional view of a first conventional horizontal rotary shuttle of a sewing machine;
Fig. 2 is an assembly sectional view of a second conventional horizontal rotary shuttle of a sewing machine; Fig.
3 is an exploded perspective view of a horizontal rotation shuttle of a sewing machine according to a preferred embodiment of the present invention;
Figure 4 is an assembly sectional view of Figure 3 showing the horizontal rotation shuttle of the present invention in a locked state;
5 is an enlarged view of FIG. 4;
Figure 6 is an assembly sectional view of Figure 3 showing the horizontal rotation shuttle of the present invention in an unlocked state;
7 is a cross-sectional view showing a manner of mounting the pivot pin of the horizontal rotation shuttle of the present invention; And
8 is a cross-sectional view showing a method of removing the turning pin of the horizontal rotation shuttle of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described with reference to the appended drawings for a preferred embodiment.

Referring to FIG. 3, FIG. 3 is an exploded perspective view of a horizontal rotation shuttle 30 of a sewing machine (not shown) according to a preferred embodiment of the present invention. As shown, the horizontal rotation shuttle 30 is rotatable about an axis 40 and is mainly comprised of an outer shuttle portion 31, an inner shuttle portion 32, a bobbin sheet 33, an elastic element 34, A lever 35 and a bobbin 36 as shown in Fig. The outer shuttle portion 31 includes a shuttle body 311 defining therein a receiving space 312 for holding the inner shuttle portion 32 therein. The shuttle body 311 has a bottom portion to which a drive shaft (not shown) of the sewing machine is fixedly connected.

The inner shuttle portion 32 is freely rotatably held in the receiving space 312 and includes a round cup-shaped body 321. The cup-shaped body 321 includes a hollow shuttle shaft 322 positioned at the center thereof to align with the shaft 40 such that the inner shuttle portion 32 defines the annular inner space 323. The shuttle shaft 322 has a notch 324 provided thereon and two pin holes 322 that are located near two lateral sides of the notch 324 and extend through the shuttle shaft 322 in the thickness direction. (325). The spring 326 is fitted in the hollow shuttle shaft 322 and the support member 327 is fitted to the upper open end of the spring 326.

The outer shuttle portion 31 and the inner shuttle portion 32 have engagement rails on their contact surfaces. More specifically, the outer shuttle portion 31 has a groove 313 in the inner wall surface and the inner shuttle portion 32 has a rail 328 on the outer wall surface that mates with the groove 313, So that the portion 31 is slidable in the outer circumferential direction relative to the inner shuttle portion 32.

The bobbin sheet 33 is fitted around the shuttle shaft 322 and includes a sleeve portion 331 and a flange portion 332. The sleeve portion 331 is located just outside the shuttle shaft 322. The flange portion 332 extends radially outwardly from the lower end of the sleeve portion 331 to define a spacing distance 334 between the flange portion 332 and the inner wall surface of the cup-shaped body 321. The flange portion 332 has an annular groove 333 (see Fig. 4) on the underside thereof. The sleeve portion 331 is provided with pin mounting holes 335 and pin removing holes 336 (see Figs. 7 and 8) at two opposed positions.

Please refer to Fig. The elastic element 34 is fitted outside the shuttle shaft 322 so as to be positioned between the inner shuttle portion 32 and the bobbin sheet 33 to push the bobbin sheet 33 to move vertically in the direction of the shaft 40 .

In the illustrated preferred embodiment, the resilient element 34 has an upwardly tapered conical spring 341 with a first turn 342 at its large end and a second turn 343 at its small end, )to be. The first pivot portion 342 presses the inner bottom portion of the cup-shaped body 321 while the second pivot portion 343 is fixed to the annular groove 333. When the conical spring 341 is compressed, the conical spring is deformed into a substantially flat state so that the bobbin sheet 33 is lowered to a position close to the inner bottom of the cup-shaped body 321.

The latch lever 35 has a pivot end 350 assembled on top of the shuttle shaft 322 and a free end 351 that selectively moves to a desired position. Further, the latch lever 35 has a stopper 352 on at least one of the two lateral edges at a position between the pivot end 350 and the free end 351. The turning end 350 includes a turning hole 353. The latch lever 35 can be pivotally and rotatably extended to the upper portion of the shuttle shaft 322 by extending the pivot pin 354 through the two pin holes 325 and the pivot hole 353 . The free end 351 is formed with a thread guide slot 355. 6, a shallow recess 356 is formed at a predetermined position near the free end 351 of the latch lever 35, which makes it convenient for the user to pull the latch lever 35. As shown in Fig.

Please refer to Fig. The pivoting end 350 includes a first contact surface 357 that is in generally contact with the support member 327 and a second contact surface 357 that is adjacent and substantially perpendicular to the first contact surface 357 358). As shown, when the first contact surface 357 contacts the support member 327, the latch lever 35 is perpendicular to the axis 40 and in a locked condition.

6, when the second contact surface 358 contacts the support member 327, the latch lever 35 is parallel to the axis 40 and in the unlocked condition. At this point, the latch lever 35 can be rotated between the locked position and the unlocked position.

The bobbin 36 includes a cylinder 361 fitted around the sleeve portion 331 of the bobbin sheet 33 and an upper flange 362 extending outwardly in the horizontal radial direction from the upper and lower ends of the cylinder 361, And a lower flange 363 to limit the yarn winding space 364 to the bobbin 36 between the cylinder 361 and the upper and lower flanges 362 and 363.

Generally, the bobbin 36 is made to have a size that is common to similar types of sewing machines. In the present invention, the bobbin 36 is mounted to the shuttle shaft 322 through the bobbin sheet 33. The sleeve portion 331 of the bobbin sheet 33 therefore has an outer diameter equal to the outer diameter of the shuttle shaft 101 of the inner shuttle portion 10 of the conventional spinning shuttle. On the other hand, the shuttle shaft 322 of the present invention has an outer diameter that is smaller than the outer diameter of the conventional shuttle shaft 101.

The present invention is characterized in that the bobbin seat (33) and the latch lever (35) jointly form restricting means for preventing the bobbin (36) from idling. On the other hand, the elastic element 34 and the latch lever 35 together form stop means for limiting the range in which the bobbin sheet 33 can be elastically forwardly pushed.

More specifically, when the latch lever 35 is selectively pivotally rotated to the lock position perpendicular to the axis 40, via the bobbin seat 33 and the restraining means formed by the latch lever 35, 36 are adjacent to the latch lever 35 and the flange portion 332 of the bobbin seat 33 so that the bobbin 36 is held between the latch lever 35 and the bobbin sheet 33 The inner shuttle portion 32 is restrained from moving. Please refer to Fig. The lower flange 363 of the bobbin 36 is adjacent the upper side of the flange portion 332 of the bobbin sheet 33 while the latch lever 35 is in the locked position, 36 are positioned higher than the upper portion of the sleeve portion 331 of the bobbin sheet 33 and pressed downward by the latch lever 35. [ Through this alignment, the bobbin 36 is prevented from idling.

And when the latch lever 35 is selectively pivotally rotated to the unlocked position parallel to the axis 40 via the stop means formed by the elastic element 34 and the latch lever 35, 33 are urged forward elastically by a resilient element 34 to a predetermined height so that the upper portion of the sleeve portion 331 abuts a stopper 352 provided on two lateral edges of the latch lever 35 . Therefore, the bobbin sheet 33 and the elastic element 34 are not separated from the inner shuttle portion 32 and are not lost in the process of exchanging the bobbin 36. [

Referring to FIG. 7, FIG. 7 shows a method of mounting the pivot pin 354 of the horizontal rotation shuttle 30 of the present invention. In the present invention, in order for the bobbin sheet 33 to be resiliently pushed to a predetermined height by the resilient element 34 to abut the stopper 352 of the latch lever 35 without interfering with the pivot pin 354 The pivot pin 354 must be fixed to the pivot hole 353 between the two pin holes 325 in the shuttle shaft 322. The pin mounting hole 335 first adjusts the height position of the bobbin sheet 33 with respect to the shuttle shaft 322 so as to align with the pin hole 325 and the turning hole 353, 354 pass through the pin fitting hole 335 and pass through the pin 354 in order to be positioned in the orbiting hole 353 between the two pin holes 325.

8, there is shown a method of removing the turning pin 354 from the shuttle shaft 322, the latch lever 35 and the bobbin sheet 33. As shown in Fig. In order to do this, first, the pin mounting hole 335 is aligned with the two pin holes 325 and the turning hole 353, and then into the pin removing hole 336 having a diameter smaller than the diameter of the turning pin 354 The tool 50 is extended. The tool 50 is then pushed onto the pivot pin 354 to cause the pivot pin 354 to move out of the sleeve portion 331 of the bobbin sheet 33 through the pin mounting hole 335.

In summary, the bobbin of the horizontal rotation shuttle of the present invention is constrained to the inner shuttle portion by the latch lever and the bobbin seat without using the conventional slide prevention spring plate. In addition, according to the present invention, a bobbin sheet that is urged forward elastically by an elastic element is finally adjacent to a stopper on the latch lever, preventing the bobbin sheet and resilient element from moving outwardly from the inner shuttle portion, Is prevented. Further, through the present invention, the bobbin sheet does not need to press the stop screw. Thus, there is no need to manufacture parts of the horizontal rotation shuttle at high manufacturing costs to allow the bobbin sheet to contact the stop screw.

It is to be understood that the invention has been described with respect to a preferred embodiment, but that many modifications or changes in the described embodiments can be made without departing from the scope and spirit of the invention, which is intended to be limited only by the appended claims.

Claims (7)

In the horizontal rotation shuttle of the sewing machine,
External shuttle portion;
An inner shuttle portion retained in the outer shuttle portion and rotatable about an axis with respect to the outer shuttle portion, the inner shuttle portion having a shuttle shaft formed therein;
A bobbin sheet fitted outside the periphery of the shuttle shaft;
An elastic element positioned between the inner shuttle portion and the bobbin sheet and resiliently pushing the bobbin sheet forward in the axial direction;
A latch lever pivotally mounted to the shuttle shaft through a pivot pin and having a stopper at at least one of the two lateral edges; And
And a bobbin fitted to the outside of the bobbin sheet;
Wherein the latch lever is a lock position perpendicular to the axis, wherein the bobbin is constrained motionlessly to the inner shuttle portion with two axially opposite ends pressed by the latch lever and the bobbin sheet, Between the unlocked position parallel to the axis, adjacent to the stopper in the latch lever, without the bobbin sheet being pushed forward elastically forward by the resilient element and eventually out of the internal shuttle portion Wherein a horizontal rotation shuttle of the sewing machine is feasible. 2. The horizontal spinning shuttle of claim 1, wherein the bobbin sheet includes a sleeve portion and a flange portion extending radially outward from a lower end of the sleeve portion. 3. The bobbin according to claim 2, wherein the bobbin is positioned higher than the upper end of the sleeve portion of the bobbin sheet, the lower end being pressed into the flange portion of the bobbin sheet, and by the latch lever when the latch lever is in the locked position And an upper end which is pressed downward. 3. The horizontal rotation shuttle of claim 2, wherein the flange portion of the bobbin sheet has an annular groove on the lower side of which the upper end of the elastic element is fixedly received. 3. The bobbin according to claim 2, wherein the sleeve portion of the bobbin sheet has pin mounting holes and pin removal holes at two opposing positions; The pivot pin extending through the pin mounting hole to pivotally connect the latch lever to the shuttle shaft; Wherein the pin removal hole has a diameter smaller than the diameter of the pivot pin but a tool can extend through the pin removal hole to push the pivot pin out of the sleeve portion through the pin mounting hole Horizontal rotating shuttle of sewing machine. 2. The horizontal rotation shuttle of claim 1, wherein the elastic element is a conical spring tapered from the bottom to the top. 2. The horizontal rotation shuttle of claim 1, wherein the latch lever further comprises a shallow recess at a predetermined position to facilitate the user to pull the latch lever.

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